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{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
\section[HsLit]{Abstract syntax: source-language literals}
-}
{-# LANGUAGE CPP, DeriveDataTypeable #-}
{-# LANGUAGE TypeSynonymInstances #-}
{-# LANGUAGE StandaloneDeriving #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE UndecidableInstances #-} -- Note [Pass sensitive types]
-- in module PlaceHolder
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE TypeFamilies #-}
module HsLit where
#include "HsVersions.h"
import GhcPrelude
import {-# SOURCE #-} HsExpr( HsExpr, pprExpr )
import BasicTypes ( IntegralLit(..),FractionalLit(..),negateIntegralLit,
negateFractionalLit,SourceText(..),pprWithSourceText )
import Type
import Outputable
import FastString
import HsExtension
import Data.ByteString (ByteString)
import Data.Data hiding ( Fixity )
{-
************************************************************************
* *
\subsection[HsLit]{Literals}
* *
************************************************************************
-}
-- Note [Literal source text] in BasicTypes for SourceText fields in
-- the following
-- Note [Trees that grow] in HsExtension for the Xxxxx fields in the following
-- | Haskell Literal
data HsLit x
= HsChar (XHsChar x) {- SourceText -} Char
-- ^ Character
| HsCharPrim (XHsCharPrim x) {- SourceText -} Char
-- ^ Unboxed character
| HsString (XHsString x) {- SourceText -} FastString
-- ^ String
| HsStringPrim (XHsStringPrim x) {- SourceText -} ByteString
-- ^ Packed bytes
| HsInt (XHsInt x) IntegralLit
-- ^ Genuinely an Int; arises from
-- @TcGenDeriv@, and from TRANSLATION
| HsIntPrim (XHsIntPrim x) {- SourceText -} Integer
-- ^ literal @Int#@
| HsWordPrim (XHsWordPrim x) {- SourceText -} Integer
-- ^ literal @Word#@
| HsInt64Prim (XHsInt64Prim x) {- SourceText -} Integer
-- ^ literal @Int64#@
| HsWord64Prim (XHsWord64Prim x) {- SourceText -} Integer
-- ^ literal @Word64#@
| HsInteger (XHsInteger x) {- SourceText -} Integer Type
-- ^ Genuinely an integer; arises only
-- from TRANSLATION (overloaded
-- literals are done with HsOverLit)
| HsRat (XHsRat x) FractionalLit Type
-- ^ Genuinely a rational; arises only from
-- TRANSLATION (overloaded literals are
-- done with HsOverLit)
| HsFloatPrim (XHsFloatPrim x) FractionalLit
-- ^ Unboxed Float
| HsDoublePrim (XHsDoublePrim x) FractionalLit
-- ^ Unboxed Double
| XLit (XXLit x)
type instance XHsChar (GhcPass _) = SourceText
type instance XHsCharPrim (GhcPass _) = SourceText
type instance XHsString (GhcPass _) = SourceText
type instance XHsStringPrim (GhcPass _) = SourceText
type instance XHsInt (GhcPass _) = NoExt
type instance XHsIntPrim (GhcPass _) = SourceText
type instance XHsWordPrim (GhcPass _) = SourceText
type instance XHsInt64Prim (GhcPass _) = SourceText
type instance XHsWord64Prim (GhcPass _) = SourceText
type instance XHsInteger (GhcPass _) = SourceText
type instance XHsRat (GhcPass _) = NoExt
type instance XHsFloatPrim (GhcPass _) = NoExt
type instance XHsDoublePrim (GhcPass _) = NoExt
type instance XXLit (GhcPass _) = NoExt
instance Eq (HsLit x) where
(HsChar _ x1) == (HsChar _ x2) = x1==x2
(HsCharPrim _ x1) == (HsCharPrim _ x2) = x1==x2
(HsString _ x1) == (HsString _ x2) = x1==x2
(HsStringPrim _ x1) == (HsStringPrim _ x2) = x1==x2
(HsInt _ x1) == (HsInt _ x2) = x1==x2
(HsIntPrim _ x1) == (HsIntPrim _ x2) = x1==x2
(HsWordPrim _ x1) == (HsWordPrim _ x2) = x1==x2
(HsInt64Prim _ x1) == (HsInt64Prim _ x2) = x1==x2
(HsWord64Prim _ x1) == (HsWord64Prim _ x2) = x1==x2
(HsInteger _ x1 _) == (HsInteger _ x2 _) = x1==x2
(HsRat _ x1 _) == (HsRat _ x2 _) = x1==x2
(HsFloatPrim _ x1) == (HsFloatPrim _ x2) = x1==x2
(HsDoublePrim _ x1) == (HsDoublePrim _ x2) = x1==x2
_ == _ = False
-- | Haskell Overloaded Literal
data HsOverLit p
= OverLit {
ol_ext :: (XOverLit p),
ol_val :: OverLitVal,
ol_witness :: HsExpr p} -- Note [Overloaded literal witnesses]
| XOverLit
(XXOverLit p)
data OverLitTc
= OverLitTc {
ol_rebindable :: Bool, -- Note [ol_rebindable]
ol_type :: Type }
deriving Data
type instance XOverLit GhcPs = NoExt
type instance XOverLit GhcRn = Bool -- Note [ol_rebindable]
type instance XOverLit GhcTc = OverLitTc
type instance XXOverLit (GhcPass _) = NoExt
-- Note [Literal source text] in BasicTypes for SourceText fields in
-- the following
-- | Overloaded Literal Value
data OverLitVal
= HsIntegral !IntegralLit -- ^ Integer-looking literals;
| HsFractional !FractionalLit -- ^ Frac-looking literals
| HsIsString !SourceText !FastString -- ^ String-looking literals
deriving Data
negateOverLitVal :: OverLitVal -> OverLitVal
negateOverLitVal (HsIntegral i) = HsIntegral (negateIntegralLit i)
negateOverLitVal (HsFractional f) = HsFractional (negateFractionalLit f)
negateOverLitVal _ = panic "negateOverLitVal: argument is not a number"
overLitType :: HsOverLit GhcTc -> Type
overLitType (OverLit (OverLitTc _ ty) _ _) = ty
overLitType XOverLit{} = panic "overLitType"
-- | Convert a literal from one index type to another, updating the annotations
-- according to the relevant 'Convertable' instance
convertLit :: (ConvertIdX a b) => HsLit a -> HsLit b
convertLit (HsChar a x) = (HsChar (convert a) x)
convertLit (HsCharPrim a x) = (HsCharPrim (convert a) x)
convertLit (HsString a x) = (HsString (convert a) x)
convertLit (HsStringPrim a x) = (HsStringPrim (convert a) x)
convertLit (HsInt a x) = (HsInt (convert a) x)
convertLit (HsIntPrim a x) = (HsIntPrim (convert a) x)
convertLit (HsWordPrim a x) = (HsWordPrim (convert a) x)
convertLit (HsInt64Prim a x) = (HsInt64Prim (convert a) x)
convertLit (HsWord64Prim a x) = (HsWord64Prim (convert a) x)
convertLit (HsInteger a x b) = (HsInteger (convert a) x b)
convertLit (HsRat a x b) = (HsRat (convert a) x b)
convertLit (HsFloatPrim a x) = (HsFloatPrim (convert a) x)
convertLit (HsDoublePrim a x) = (HsDoublePrim (convert a) x)
convertLit (XLit a) = (XLit (convert a))
{-
Note [ol_rebindable]
~~~~~~~~~~~~~~~~~~~~
The ol_rebindable field is True if this literal is actually
using rebindable syntax. Specifically:
False iff ol_witness is the standard one
True iff ol_witness is non-standard
Equivalently it's True if
a) RebindableSyntax is on
b) the witness for fromInteger/fromRational/fromString
that happens to be in scope isn't the standard one
Note [Overloaded literal witnesses]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
*Before* type checking, the HsExpr in an HsOverLit is the
name of the coercion function, 'fromInteger' or 'fromRational'.
*After* type checking, it is a witness for the literal, such as
(fromInteger 3) or lit_78
This witness should replace the literal.
This dual role is unusual, because we're replacing 'fromInteger' with
a call to fromInteger. Reason: it allows commoning up of the fromInteger
calls, which wouldn't be possible if the desugarer made the application.
The PostTcType in each branch records the type the overload literal is
found to have.
-}
-- Comparison operations are needed when grouping literals
-- for compiling pattern-matching (module MatchLit)
instance (Eq (XXOverLit p)) => Eq (HsOverLit p) where
(OverLit _ val1 _) == (OverLit _ val2 _) = val1 == val2
(XOverLit val1) == (XOverLit val2) = val1 == val2
_ == _ = panic "Eq HsOverLit"
instance Eq OverLitVal where
(HsIntegral i1) == (HsIntegral i2) = i1 == i2
(HsFractional f1) == (HsFractional f2) = f1 == f2
(HsIsString _ s1) == (HsIsString _ s2) = s1 == s2
_ == _ = False
instance (Ord (XXOverLit p)) => Ord (HsOverLit p) where
compare (OverLit _ val1 _) (OverLit _ val2 _) = val1 `compare` val2
compare (XOverLit val1) (XOverLit val2) = val1 `compare` val2
compare _ _ = panic "Ord HsOverLit"
instance Ord OverLitVal where
compare (HsIntegral i1) (HsIntegral i2) = i1 `compare` i2
compare (HsIntegral _) (HsFractional _) = LT
compare (HsIntegral _) (HsIsString _ _) = LT
compare (HsFractional f1) (HsFractional f2) = f1 `compare` f2
compare (HsFractional _) (HsIntegral _) = GT
compare (HsFractional _) (HsIsString _ _) = LT
compare (HsIsString _ s1) (HsIsString _ s2) = s1 `compare` s2
compare (HsIsString _ _) (HsIntegral _) = GT
compare (HsIsString _ _) (HsFractional _) = GT
-- Instance specific to GhcPs, need the SourceText
instance p ~ GhcPass pass => Outputable (HsLit p) where
ppr (HsChar st c) = pprWithSourceText st (pprHsChar c)
ppr (HsCharPrim st c) = pp_st_suffix st primCharSuffix (pprPrimChar c)
ppr (HsString st s) = pprWithSourceText st (pprHsString s)
ppr (HsStringPrim st s) = pprWithSourceText st (pprHsBytes s)
ppr (HsInt _ i)
= pprWithSourceText (il_text i) (integer (il_value i))
ppr (HsInteger st i _) = pprWithSourceText st (integer i)
ppr (HsRat _ f _) = ppr f
ppr (HsFloatPrim _ f) = ppr f <> primFloatSuffix
ppr (HsDoublePrim _ d) = ppr d <> primDoubleSuffix
ppr (HsIntPrim st i) = pprWithSourceText st (pprPrimInt i)
ppr (HsWordPrim st w) = pprWithSourceText st (pprPrimWord w)
ppr (HsInt64Prim st i) = pp_st_suffix st primInt64Suffix (pprPrimInt64 i)
ppr (HsWord64Prim st w) = pp_st_suffix st primWord64Suffix (pprPrimWord64 w)
ppr (XLit x) = ppr x
pp_st_suffix :: SourceText -> SDoc -> SDoc -> SDoc
pp_st_suffix NoSourceText _ doc = doc
pp_st_suffix (SourceText st) suffix _ = text st <> suffix
-- in debug mode, print the expression that it's resolved to, too
instance (p ~ GhcPass pass, OutputableBndrId p)
=> Outputable (HsOverLit p) where
ppr (OverLit {ol_val=val, ol_witness=witness})
= ppr val <+> (whenPprDebug (parens (pprExpr witness)))
ppr (XOverLit x) = ppr x
instance Outputable OverLitVal where
ppr (HsIntegral i) = pprWithSourceText (il_text i) (integer (il_value i))
ppr (HsFractional f) = ppr f
ppr (HsIsString st s) = pprWithSourceText st (pprHsString s)
-- | pmPprHsLit pretty prints literals and is used when pretty printing pattern
-- match warnings. All are printed the same (i.e., without hashes if they are
-- primitive and not wrapped in constructors if they are boxed). This happens
-- mainly for too reasons:
-- * We do not want to expose their internal representation
-- * The warnings become too messy
pmPprHsLit :: HsLit (GhcPass x) -> SDoc
pmPprHsLit (HsChar _ c) = pprHsChar c
pmPprHsLit (HsCharPrim _ c) = pprHsChar c
pmPprHsLit (HsString st s) = pprWithSourceText st (pprHsString s)
pmPprHsLit (HsStringPrim _ s) = pprHsBytes s
pmPprHsLit (HsInt _ i) = integer (il_value i)
pmPprHsLit (HsIntPrim _ i) = integer i
pmPprHsLit (HsWordPrim _ w) = integer w
pmPprHsLit (HsInt64Prim _ i) = integer i
pmPprHsLit (HsWord64Prim _ w) = integer w
pmPprHsLit (HsInteger _ i _) = integer i
pmPprHsLit (HsRat _ f _) = ppr f
pmPprHsLit (HsFloatPrim _ f) = ppr f
pmPprHsLit (HsDoublePrim _ d) = ppr d
pmPprHsLit (XLit x) = ppr x
-- | @'hsLitNeedsParens' p l@ returns 'True' if a literal @l@ needs
-- to be parenthesized under precedence @p@.
hsLitNeedsParens :: PprPrec -> HsLit x -> Bool
hsLitNeedsParens p = go
where
go (HsChar {}) = False
go (HsCharPrim {}) = False
go (HsString {}) = False
go (HsStringPrim {}) = False
go (HsInt _ x) = p > topPrec && il_neg x
go (HsIntPrim _ x) = p > topPrec && x < 0
go (HsWordPrim {}) = False
go (HsInt64Prim _ x) = p > topPrec && x < 0
go (HsWord64Prim {}) = False
go (HsInteger _ x _) = p > topPrec && x < 0
go (HsRat _ x _) = p > topPrec && fl_neg x
go (HsFloatPrim _ x) = p > topPrec && fl_neg x
go (HsDoublePrim _ x) = p > topPrec && fl_neg x
go (XLit _) = False
-- | @'hsOverLitNeedsParens' p ol@ returns 'True' if an overloaded literal
-- @ol@ needs to be parenthesized under precedence @p@.
hsOverLitNeedsParens :: PprPrec -> HsOverLit x -> Bool
hsOverLitNeedsParens p (OverLit { ol_val = olv }) = go olv
where
go :: OverLitVal -> Bool
go (HsIntegral x) = p > topPrec && il_neg x
go (HsFractional x) = p > topPrec && fl_neg x
go (HsIsString {}) = False
hsOverLitNeedsParens _ (XOverLit { }) = False
|